CN117800426B - Wool washing wastewater recovery device - Google Patents

Abstract

The invention relates to the technical field of wastewater treatment, in particular to a wool washing wastewater recovery device, which comprises a wastewater tank and a square shell arranged at the upper end of the wastewater tank, wherein the upper end of the wastewater tank is symmetrically and fixedly connected with a fixed plate, the inner walls of the wastewater tank are fixedly provided with grid meshes, the inner walls of the two fixed plates are jointly and rotatably provided with rotary drums in a penetrating and rotating mode, the inner walls of the rotary drums are provided with a plurality of rotary shafts in a penetrating and rotating mode in a linear array mode from front to back, and the rear end of the rotary drums is provided with a driving mechanism. The hook can also be subjected to left-right shaking and front-back shaking, so that the unhooking rate of the filiform residual wool is improved.

Description

Wool washing wastewater recovery device

Technical Field

The invention relates to the technical field of wastewater treatment, in particular to a wool washing wastewater recovery device.

Background

Wool washing wastewater refers to wastewater used for washing wool in the production or processing process of wool. The waste water generally contains organic matters, grease, filiform residual wool, particulate matters and other impurities, the direct discharge of the wool washing waste water can cause harm to the ecological system of the water body, and the grease in the wool is a substance with utilization value, so that the wool washing waste water needs to be purified and the grease needs to be recovered.

When the existing wool washing wastewater is treated, large impurities such as filiform residual wool, particulate matters and the like are primarily filtered through a mechanical grid, and then the wastewater is purified in the next step. However, the filiform residual wool in the wastewater is often mixed with large impurities such as particles and the like and is intercepted by a mechanical grating, the filiform residual wool and the large impurities such as the particles and the like are difficult to separate and are often discarded together, when the wool is processed in a large scale, the more the filiform wool is remained when the wool is cleaned, the wool is a valuable natural fiber, and discarding the residual filiform wool wastes the reusable resources. For this purpose, we propose a wool washing wastewater recovery device.

Disclosure of Invention

The invention aims to provide a wool washing wastewater recovery device for solving the problems in the background technology.

In order to achieve the above purpose, the present invention provides the following technical solutions: the utility model provides a wool washing waste water recovery unit, includes the waste water tank and installs the square shell in the waste water tank upper end, the upper end symmetry fixedly connected with fixed plate of waste water tank, and the inner wall fixed mounting of waste water tank has the grid net, two the inner wall of fixed plate runs through jointly and rotates and install the rotary drum, the inner wall of rotary drum runs through from the past back linear array and rotates and install a plurality of pivots, and the rear end of rotary drum is equipped with actuating mechanism, a plurality of be equipped with slewing mechanism between top and the rotary drum of pivot, and the bottom of a plurality of pivots all is connected with the revolving column through elastic component, many all the slip cap is equipped with the sleeve pipe on the outer wall of revolving column, many telescopic outer wall all from last down linear array fixedly connected with multiunit couple, and all be equipped with elastic mechanism between many sleeve pipes and the many revolving columns respectively, the upper end fixed mounting of square shell has the fan, and the bottom of square shell is equipped with dodging mechanism, and the inboard top and the lateral wall of square shell are equipped with first shake subassembly and second shake subassembly respectively.

Preferably, the driving mechanism comprises an L-shaped plate, the L-shaped plate is fixedly connected to the rear end of the wastewater tank, a first motor is fixedly arranged on the vertical wall of the L-shaped plate in a penetrating mode, and the output shaft end of the first motor is fixedly connected with the rear end of the rotary drum.

Preferably, the rotating mechanism comprises a connecting column, a second motor and a plurality of second bevel gears, the second motor is fixedly arranged at the front end of the rotary drum, one end of the connecting column is rotationally connected at the rear end of the rotary drum, the other end of the connecting column movably penetrates through the front end of the rotary drum, the other end of the connecting column is fixedly connected with the output shaft end of the second motor, the connecting column is located above the plurality of rotary shafts, a plurality of first bevel gears are fixedly sleeved on the outer wall of the connecting column, a plurality of second bevel gears are fixedly connected to the top ends of the plurality of rotary shafts respectively, and the plurality of second bevel gears are meshed with the plurality of first bevel gears respectively.

Preferably, the elastic component comprises an L-shaped block, the L-shaped block is fixedly connected to the bottom end of the rotating shaft, a guide column is inserted in the vertical wall of the L-shaped block in a sliding mode, the rear end of the guide column is fixedly connected with the outer wall of the rotating column, a first spring is sleeved on the outer wall of the guide column in a sliding mode, and the first spring is fixedly connected between the outer wall of the rotating column and the vertical wall of the L-shaped block.

Preferably, the elastic mechanism comprises two U-shaped blocks and two U-shaped blocks, wherein the two U-shaped blocks are symmetrically and fixedly connected to the outer wall of the rotary column, the two U-shaped blocks are symmetrically and fixedly connected to the edge of the upper part of the outer wall of the sleeve, the upper ends of the two U-shaped blocks are fixedly connected with connecting rods, the two connecting rods respectively and movably penetrate through the upper ends of the two U-shaped blocks, connecting discs are fixedly connected to the top ends of the two connecting rods respectively, the connecting discs are slidably sleeved on the outer wall of the rotary column, springs II are respectively and fixedly connected between the U-shaped blocks and the U-shaped blocks in a sliding mode, and the springs II are slidably sleeved on the outer wall of the connecting rods.

Preferably, the first shake subassembly includes many dead levers, and is many from the linear array fixed connection in the inboard top of square shell back, and the equal fixedly connected with arc of many dead lever outer wall lower part edge, polylith the equal fixedly connected with arc lug two of extrados of arc.

Preferably, the second shaking assembly comprises a plurality of connecting frames, the connecting frames are fixedly connected to the edge of the upper portion of the side wall of the square shell in a front-to-back linear array mode, the bottom ends of the connecting frames are fixedly connected with sector plates, and the front ends of the sector plates are fixedly connected with arc-shaped protruding blocks I.

Preferably, the avoiding mechanism comprises two electric push rods, the two electric push rods are respectively and fixedly arranged at the edges of the upper parts of the front end and the rear end of the wastewater tank, the telescopic shaft ends of the two electric push rods are fixedly connected with splicing blocks, the two splicing blocks are fixedly connected with splicing plates together at the top ends of the splicing blocks, the splicing plates are attached to the upper ends of the wastewater tank, the side walls of the splicing plates are fixedly connected with a plurality of plugboards in a linear array mode from front to back, the plurality of plugboards are all in sliding penetration in the inner wall of the bottom end of the square shell, and the edges of the plurality of plugboards, which are far away from the splicing plates, are fixedly connected with scraping plates together.

Compared with the prior art, the invention has the beneficial effects that:

1. After the wool washing wastewater recovery device performs preliminary filtration on the wastewater, the filtered filiform residual wool can be well separated from large impurities such as particulate matters in the wastewater in the continuous hooking water of the hooks which perform revolution and rotation, and the hooked filiform residual wool can automatically fall down to be collected through the cooperation of fan blowing and hook rotation, so that valuable wool is prevented from being wasted.

2. The hook can also be subjected to left-right shaking and front-back shaking, so that the filiform residual wool can be further separated from the hook rapidly, the filiform residual wool which is intractable on the hook is not easy to hook continuously by the hook, and the unhooking rate of the filiform residual wool is improved.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present invention;

FIG. 2 is a cross-sectional view of the drum and two stationary plates of the present invention;

FIG. 3 is an enlarged view of the structure of FIG. 2A in accordance with the present invention;

FIG. 4 is an enlarged view of the structure of FIG. 2B in accordance with the present invention;

FIG. 5 is a structural representation at the square shell of the present invention;

FIG. 6 is an illustration of the present invention at a connector;

FIG. 7 is an illustration of the present invention at a securing lever;

FIG. 8 is a structural representation of the grid mesh and drum of the present invention;

FIG. 9 is an enlarged view of the structure of FIG. 6 at C in accordance with the present invention;

fig. 10 is an enlarged view of the structure of fig. 7D according to the present invention.

In the drawings, the list of components represented by the various numbers is as follows: 1. a blower; 2. a square shell; 3. a rotating drum; 4. a first motor; 5. an L-shaped plate; 6. a rotating column; 7. a waste water tank; 8. a fixing plate; 9. a second motor; 10. an electric push rod; 11. splicing blocks; 12. splice plates; 13. a connecting column; 14. bevel gears I; 15. a grid mesh; 16. bevel gears II; 17. a rotating shaft; 18. a first spring; 19. a guide post; 20. an L-shaped block; 21. a connecting disc; 22. a U-shaped block; 23. a U-shaped block; 24. a sleeve; 25. a hook; 26. a second spring; 27. a connecting rod; 28. a connecting frame; 29. a fixed rod; 30. a sector plate; 31. a scraper; 32. inserting plate; 33. arc-shaped protruding blocks I; 34. arc-shaped convex blocks II; 35. an arc-shaped plate.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Example 1

Referring to fig. 1-10, a wool washing wastewater recycling device in the drawings includes a wastewater tank 7 and a square shell 2 mounted at the upper end of the wastewater tank 7, wherein the upper end of the wastewater tank 7 is symmetrically and fixedly connected with a fixing plate 8, the inner wall of the wastewater tank 7 is fixedly provided with a grid mesh 15, the inner walls of the two fixing plates 8 jointly penetrate through and rotate and are provided with a rotary drum 3, the inner wall of the rotary drum 3 penetrates through and rotates from front to back in a linear array manner, the rear end of the rotary drum 3 is provided with a driving mechanism, a rotating mechanism is arranged between the top ends of the rotary shafts 17 and the rotary drum 3, the bottom ends of the rotary shafts 17 are connected with rotary columns 6 through elastic components, sleeves 24 are sleeved on the outer walls of the rotary columns 6 in a sliding manner, the outer walls of the sleeves 24 are fixedly connected with a plurality of groups of hooks 25 from top to bottom in a linear array manner, elastic mechanisms are respectively arranged between the sleeves 24 and the rotary columns 6, the upper end of the square shell 2 is fixedly provided with a fan 1, the bottom end of the square shell 2 is provided with a avoidance mechanism, and the inner side top end of the square shell 2 and the side wall of the square shell 2 is respectively provided with a first component and a second shaking component.

Referring to fig. 1,2 and 8, in the drawings, the driving mechanism includes an L-shaped plate 5,L fixedly connected to the rear end of the wastewater tank 7, a motor one 4 is fixedly installed through a vertical wall of the L-shaped plate 5, and an output shaft end of the motor one 4 is fixedly connected to the rear end of the drum 3.

Referring to fig. 2 and 3, in the drawings, the rotating mechanism includes a connecting post 13, a second motor 9 and a plurality of second bevel gears 16, the second motor 9 is fixedly mounted at the front end of the drum 3, one end of the connecting post 13 is rotatably connected at the rear end of the drum 3, the other end of the connecting post 13 movably penetrates through the front end of the drum 3, the other end of the connecting post 13 is fixedly connected with the output shaft end of the second motor 9, the connecting post 13 is located above the plurality of rotating shafts 17, the outer wall of the connecting post 13 is fixedly sleeved with the plurality of first bevel gears 14, the plurality of second bevel gears 16 are respectively fixedly connected at the top ends of the plurality of rotating shafts 17, and the plurality of second bevel gears 16 are respectively meshed with the plurality of first bevel gears 14.

Referring to fig. 1 and 5, in the illustration, the avoiding mechanism includes two electric push rods 10, the two electric push rods 10 are respectively and fixedly installed at the edges of the upper portions of the front end and the rear end of the wastewater tank 7, the telescopic shaft ends of the two electric push rods 10 are fixedly connected with splicing blocks 11, the tops of the two splicing blocks 11 are fixedly connected with splicing plates 12 together, the splicing plates 12 are attached to the upper ends of the wastewater tank 7, the side walls of the splicing plates 12 are fixedly connected with a plurality of inserting plates 32 in a linear array from front to back, the plurality of inserting plates 32 are respectively and slidably inserted into the inner walls of the bottom end of the square shell 2, and the edges of the upper ends of the plurality of inserting plates 32, which are far away from the splicing plates 12, are fixedly connected with scraping plates 31 together.

In this embodiment, wool washing wastewater can be introduced into the wastewater tank 7, and the wastewater can pass through the grid mesh 15, so that large impurities such as filiform residual wool and particulate matters in the wastewater are intercepted by the grid mesh 15. Then, the motor I4 is started, the motor I4 can drive the rotary drum 3 to rotate in the inner walls of the two fixed plates 8, the rotary drum 3 can drive the rotary shafts 17, the rotary posts 6, the sleeves 24 and the hooks 25 on the outer walls of the sleeves 24 to rotate clockwise, meanwhile, the motor II 9 is started, the motor II 9 can drive the connecting posts 13 to rotate in the inner walls of the rotary drum 3, the connecting posts 13 can drive the bevel gears I14 to rotate, the bevel gears II 16 meshed with the bevel gears I14 can be driven by the bevel gears II can drive the rotary shafts 17 connected with the bevel gears I, the rotary posts 6, the sleeves 24 and the hooks 25 on the outer walls of the sleeves 24 can rotate, the rotary hooks 25 can easily hook the silk-like wool in the waste water continuously, and large impurities such as particles are difficult to hook by the hooks 25, so that the silk-like residual wool in the waste water can leave independently, when the sleeves 24 leave the water surface, the motor II 9 is closed to stop the rotation of the hooks 25, the silk-like wool from being thrown off, the inner side of the hooks, the silk-like wool can be prevented from being blown off, the silk-like wool can be continuously hooked by the rotary drum 1 with the rotary drum 6, the sleeves 24 can be driven by the rotary posts II can be driven by the rotary shafts 6, the silk-like wool can be well hook the hooks 1 to the inner side of the hooks 2, and the silk-like wool can be opened by the fan 1, and the silk-like can be well opened by the hook 1, and the silk-like wool can be turned by the hook 2.

When the plurality of sleeves 24 rotate to be close to the inner bottom end of the square shell 2, the two electric push rods 10 are started, the telescopic rods of the two electric push rods 10 are stretched, the two electric push rods 10 can drive the connected splicing blocks 11 to move away from the square shell 2, the splicing plates 12 connected with the upper ends of the two splicing blocks 11 can slide in the inner bottom end wall of the square shell 2 with the plurality of inserting plates 32, the plurality of inserting plates 32 can slide in the inner bottom end of the square shell 2 with the scraping plates 31, the scraping plates 31 can scrape the filiform residual wool at the inner bottom end of the square shell 2 to the inner side surface of the square shell 2, the filiform residual wool on the surfaces of the plurality of inserting plates 32 is conveyed to the lower edge of the inner side surface of the square shell 2, and the filiform residual wool is collected so as to be conveniently taken out, at the moment, a plurality of gaps are formed at the inner bottom end of the square shell 2 for the plurality of rotary posts 6, the plurality of sleeves 24 and hooks 25 on the outer walls of the plurality of sleeves 24 to pass through, and then the rotary posts 6 and the plurality of sleeves 24 and the hooks 25 on the outer walls of the plurality of sleeves 24 are hooked into the filiform wool in the next time.

It should be noted that, this wool washing waste water recovery unit carries out preliminary filtration to waste water after, and filiform residual wool that filters down can be by continuous hook go out in water, with the fine separation of big impurity such as particulate matter in the waste water, and hook filiform residual wool can be through fan 1 bloies and couple 25 pivoted cooperation and automatic whereabouts is collected, avoids valuable wool to be wasted.

Example two

Referring to fig. 3, for further explanation of the embodiment, the elastic component in the illustration includes an L-shaped block 20, the L-shaped block 20 is fixedly connected to the bottom end of the rotating shaft 17, a guide post 19 is slidably inserted into a vertical wall of the L-shaped block 20, the rear end of the guide post 19 is fixedly connected to the outer wall of the rotating post 6, a first spring 18 is slidably sleeved on the outer wall of the guide post 19, and the first spring 18 is fixedly connected between the outer wall of the rotating post 6 and the vertical wall of the L-shaped block 20.

Referring to fig. 4, in the illustration, the elastic mechanism includes two U-shaped blocks 22 and two U-shaped blocks 23, the two U-shaped blocks 22 are symmetrically and fixedly connected to the outer wall of the rotating column 6, the two U-shaped blocks 23 are symmetrically and fixedly connected to the upper edge of the outer wall of the sleeve 24, the upper ends of the two U-shaped blocks 23 are fixedly connected with connecting rods 27, the two connecting rods 27 respectively penetrate through the upper ends of the two U-shaped blocks 22, the top ends of the two connecting rods 27 are fixedly connected with connecting discs 21, the connecting discs 21 are slidably sleeved on the outer wall of the rotating column 6, the outer walls of the two connecting rods 27 are slidably sleeved with springs two 26, and the springs two 26 are fixedly connected between the U-shaped blocks 22 and the U-shaped blocks 23.

Referring to fig. 5, 7 and 10, in the drawings, the first shaking assembly includes a plurality of fixing rods 29, the plurality of fixing rods 29 are fixedly connected to the inner top end of the square shell 2 in a front-to-back linear array, arc plates 35 are fixedly connected to edges of lower portions of outer walls of the plurality of fixing rods 29, and arc protrusions 34 are fixedly connected to outer arc surfaces of the plurality of arc plates 35.

Referring to fig. 5, 6 and 9, the second shaking assembly in the drawings includes a plurality of connecting frames 28, the plurality of connecting frames 28 are fixedly connected to the upper edge of the side wall of the square housing 2 in a linear array from front to back, the bottom ends of the plurality of connecting frames 28 are fixedly connected to a sector plate 30, and the front ends of the plurality of sector plates 30 are fixedly connected to a plurality of arc-shaped protruding blocks 33.

In this embodiment, each spindle 17 is elastically connected to the first spring 18 and the corresponding one of the rotary posts 6 through an L-shaped block 20 and a guide post 19, and each sleeve 24 is elastically connected to the second spring 26 and the corresponding one of the rotary posts 6 through two U-shaped blocks 22, two U-shaped blocks 23, two connecting rods 27 and a connecting disc 21. The rotation of the rotating shaft 17 can drive the rotating column 6 to rotate, and the rotation of the rotating column 6 can drive the sleeve 24 to rotate.

When each rotating post 6 and each sleeve 24 rotate to the inner side of the square shell 2 just before entering, each sleeve 24 drives a connecting disc 21 on the outer wall of the sleeve to slide on the outer wall of a corresponding arc-shaped plate 35, the connecting disc 21 moves away from the arc-shaped plate 35 through a second arc-shaped lug 34 on the outer wall of the arc-shaped plate 35, the connecting disc 21 drives two connecting rods 27 to move together, the two connecting rods 27 can slide in the inner walls of the two U-shaped blocks 22 respectively, the two connecting rods 27 can drive the U-shaped blocks 23 connected respectively to move together, the two U-shaped blocks 23 can drive the sleeve 24 connected between the two U-shaped blocks 23 to slide on the outer wall of the rotating post 6, a first spring 18 connected between the U-shaped blocks 22 and the U-shaped blocks 23 can be stretched, and when the connecting disc 21 leaves the second arc-shaped lug 34, the connecting disc 21, the two U-shaped blocks 23, the two connecting rods 27 and the sleeve 24 can reset together, and a hook 25 outside the sleeve 24 can shake left and right.

When each rotating column 6 rotates to the corresponding sector plate 30, at this time, each rotating column 6 passes through the first arc-shaped protrusions 33 on the outer wall of the sector plate 30, in the process, the rotating column 6 moves away from the sector plate 30, the rotating column 6 presses the first spring 18 connected with the L-shaped block 20, the rotating column 6 drives the guide column 19 to slide in the inner wall of the L-shaped block 20, the rotating column 6 drives the sleeve 24 to move together, and when each rotating column 6 leaves the first arc-shaped protrusion 33, the rotating column 6 and the sleeve 24 reset under the action of the first spring 18 until the rotating column 6 leaves the first arc-shaped protrusion 33, and the hooks 25 outside the sleeve 24 shake forwards and backwards.

It should be noted that, when the filiform residual wool hooked on the hook 25 is separated from the inner side of the square shell 2, the hook 25 can also shake left and right and shake front and back, so that the filiform residual wool can further leave the hook 25 rapidly, some filiform residual wool which is intractable on the hook 25 is not easy to be hooked by the hook 25 continuously, and the unhooking rate of the filiform residual wool is improved.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (4)

1. The utility model provides a wool washing waste water recovery unit, includes waste water tank (7) and installs square shell (2) in waste water tank (7) upper end, its characterized in that: the upper end symmetry fixedly connected with fixed plate (8) of waste water tank (7), and the inner wall fixed mounting of waste water tank (7) has grid net (15), two the inner wall of fixed plate (8) runs through jointly and rotates and install rotary drum (3), the inner wall of rotary drum (3) runs through from front to back and rotates and install a plurality of pivots (17), and the rear end of rotary drum (3) is equipped with actuating mechanism, a plurality of be equipped with rotary mechanism between top and rotary drum (3) of pivot (17), and the bottom of a plurality of pivots (17) all is connected with swivel post (6) through elastic component, a plurality of all slip cap is equipped with sleeve pipe (24) on the outer wall of swivel post (6), a plurality of sleeve pipe (24) all from top down linear array fixedly connected with multiunit couple (25), and all be equipped with elastic mechanism between a plurality of sleeve pipes (24) and a plurality of swivel post (6) respectively, the upper end of Fang Ke (2) is fixedly equipped with fan (1), and the bottom of square shell (2) is equipped with dodging mechanism, and square shell (2) top and side wall and first side wall and second shake subassembly respectively;

The elastic assembly comprises an L-shaped block (20), the L-shaped block (20) is fixedly connected to the bottom end of the rotating shaft (17), a guide column (19) is inserted into the vertical wall of the L-shaped block (20) in a sliding manner, the rear end of the guide column (19) is fixedly connected with the outer wall of the rotating column (6), a first spring (18) is sleeved on the outer wall of the guide column (19) in a sliding manner, and the first spring (18) is fixedly connected between the outer wall of the rotating column (6) and the vertical wall of the L-shaped block (20);

The elastic mechanism comprises two U-shaped blocks (22) and two U-shaped blocks (23), wherein the two U-shaped blocks (22) are symmetrically and fixedly connected to the outer wall of the rotary column (6), the two U-shaped blocks (23) are symmetrically and fixedly connected to the upper edge of the outer wall of the sleeve (24), connecting rods (27) are fixedly connected to the upper ends of the two U-shaped blocks (23), the two connecting rods (27) respectively penetrate through the upper ends of the two U-shaped blocks (22) in a movable mode, connecting discs (21) are fixedly connected to the top ends of the two connecting rods (27) together, the connecting discs (21) are slidably sleeved on the outer wall of the rotary column (6), springs II (26) are slidably sleeved on the outer walls of the two connecting rods (27), and the springs II (26) are fixedly connected between the U-shaped blocks (22) and the U-shaped blocks (23);

The first shaking assembly comprises a plurality of fixing rods (29), the fixing rods (29) are linearly connected to the top end of the inner side of the square shell (2) in a front-to-back mode in a linear array mode, arc plates (35) are fixedly connected to the edges of the lower portions of the outer walls of the fixing rods (29), and arc-shaped protruding blocks II (34) are fixedly connected to the outer arc surfaces of the arc plates (35);

the second shaking assembly comprises a plurality of connecting frames (28), the connecting frames (28) are fixedly connected to the edge of the upper portion of the side wall of the square shell (2) in a linear array mode from front to back, the bottom ends of the connecting frames (28) are fixedly connected with sector plates (30), and the front ends of the sector plates (30) are fixedly connected with arc-shaped protruding blocks (33).

2. A wool scouring wastewater recovery device according to claim 1, wherein: the driving mechanism comprises an L-shaped plate (5), the L-shaped plate (5) is fixedly connected to the rear end of the wastewater tank (7), a first motor (4) is fixedly arranged on the vertical wall of the L-shaped plate (5) in a penetrating mode, and the output shaft end of the first motor (4) is fixedly connected with the rear end of the rotary drum (3).

3. A wool scouring wastewater recovery device according to claim 1, wherein: the rotating mechanism comprises a connecting column (13), a motor II (9) and a plurality of bevel gears II (16), wherein the motor II (9) is fixedly arranged at the front end of the rotary drum (3), one end of the connecting column (13) is rotationally connected to the rear end of the interior of the rotary drum (3), the other end of the connecting column (13) movably penetrates through the front end of the rotary drum (3), the other end of the connecting column (13) is fixedly connected with the output shaft end of the motor II (9), the connecting column (13) is located above the plurality of rotary shafts (17), a plurality of bevel gears I (14) are fixedly sleeved on the outer wall of the connecting column (13), the bevel gears II (16) are fixedly connected to the top ends of the plurality of rotary shafts (17) respectively, and the bevel gears II (16) are meshed with the bevel gears I (14) respectively.

4. A wool scouring wastewater recovery device according to claim 1, wherein: the avoidance mechanism comprises two electric push rods (10), the two electric push rods (10) are fixedly mounted at the edges of the upper parts of the front end and the rear end of the waste water tank (7) respectively, telescopic shaft ends of the two electric push rods (10) are fixedly connected with splicing blocks (11), the two splicing blocks (11) are fixedly connected with splicing plates (12) together at the top ends of the splicing blocks (11), the splicing plates (12) are attached to the upper ends of the waste water tank (7), the side walls of the splicing plates (12) are fixedly connected with a plurality of inserting plates (32) from front to back in a linear array manner, the plurality of inserting plates (32) are all slidably inserted into the inner walls of the bottom end of the square shell (2), and the edges of the plurality of inserting plates (32) away from the splicing plates (12) are fixedly connected with scraping plates (31) together.